Add to ORKGThe first set of hydrogen reduction experiments to use actual lunar material was recently completed. The sample, 70035, is a coarse-grained vesicular basalt containing 18.46 wt. percent FeO and 12.97 wt. percent TiO2. The mineralogy includes pyroxene, ilmenite, plagioclase, and minor olivine. The sample was crushed to a grain size of less than 500 microns. The crushed basalt was reduced with hydrogen in seven tests at temperatures of 900-1050 C and pressures of 1-10 atm for 30-60 minutes. A capacitance probe, measuring the dew point of the gas stream, was used to follow reaction progress. Experiments were also conducted using a terrestrial basalt similar to some lunar mare samples. Minnesota Lunar Simulant (MLS-1) contains 13.29 wt. percent...
One of the most important commodities lacking in the moon is free oxygen which is required for life ...
Future human lunar habitation requires using in situ materials for both structural components and ox...
Because it is energetically easier to get material from the Moon to Earth orbit than from the Earth ...
The Carbotek/Shimizu process to produce oxygen from lunar soils has been successfully demonstrated o...
The most abundant element in lunar rocks and soils is oxygen which makes up approximately 45 percent...
In the past 20 years, considerable attention been paid to returning to our natural satellite with r...
Mare soil and orange and black pyroclastic glass were reduced in hydrogen gas at temperatures of 900...
In the past 20 years, considerable attention been paid to returning to our natural satellite with ro...
Future human habitation of the Moon will likely require the use of locally derived materials because...
In situ resource utilisation (ISRU) refers to the extraction and use of local materials, and numerou...
Hydrogen reduction of lunar regolith has been proposed as a viable technology for oxygen production ...
Future human habitation of the Moon will likely require the use of locally derived materials because...
To achieve permanent human presence and activity on the moon, oxygen is required for both life suppo...
Hawke et al. (1990) suggest that ilmenite found in Apollo 17-type pyroclastic glass may provide feed...
Since March 1, 1989, attention was concentrated on the extraction of ilmenite from extraterrestrial ...
One of the most important commodities lacking in the moon is free oxygen which is required for life ...
Future human lunar habitation requires using in situ materials for both structural components and ox...
Because it is energetically easier to get material from the Moon to Earth orbit than from the Earth ...
The Carbotek/Shimizu process to produce oxygen from lunar soils has been successfully demonstrated o...
The most abundant element in lunar rocks and soils is oxygen which makes up approximately 45 percent...
In the past 20 years, considerable attention been paid to returning to our natural satellite with r...
Mare soil and orange and black pyroclastic glass were reduced in hydrogen gas at temperatures of 900...
In the past 20 years, considerable attention been paid to returning to our natural satellite with ro...
Future human habitation of the Moon will likely require the use of locally derived materials because...
In situ resource utilisation (ISRU) refers to the extraction and use of local materials, and numerou...
Hydrogen reduction of lunar regolith has been proposed as a viable technology for oxygen production ...
Future human habitation of the Moon will likely require the use of locally derived materials because...
To achieve permanent human presence and activity on the moon, oxygen is required for both life suppo...
Hawke et al. (1990) suggest that ilmenite found in Apollo 17-type pyroclastic glass may provide feed...
Since March 1, 1989, attention was concentrated on the extraction of ilmenite from extraterrestrial ...
One of the most important commodities lacking in the moon is free oxygen which is required for life ...
Future human lunar habitation requires using in situ materials for both structural components and ox...
Because it is energetically easier to get material from the Moon to Earth orbit than from the Earth ...